[deliverable/linux.git] / Documentation / filesystems / sysfs.txt


sysfs - _The_ filesystem for exporting kernel objects. 

Patrick Mochel	<mochel@osdl.org>

10 January 2003


What it is:
~~~~~~~~~~~

sysfs is a ram-based filesystem initially based on ramfs. It provides
a means to export kernel data structures, their attributes, and the 
linkages between them to userspace. 

sysfs is tied inherently to the kobject infrastructure. Please read
Documentation/kobject.txt for more information concerning the kobject
interface. 


Using sysfs
~~~~~~~~~~~

sysfs is always compiled in. You can access it by doing:

    mount -t sysfs sysfs /sys 


Directory Creation
~~~~~~~~~~~~~~~~~~

For every kobject that is registered with the system, a directory is
created for it in sysfs. That directory is created as a subdirectory
of the kobject's parent, expressing internal object hierarchies to
userspace. Top-level directories in sysfs represent the common
ancestors of object hierarchies; i.e. the subsystems the objects
belong to. 

Sysfs internally stores the kobject that owns the directory in the
->d_fsdata pointer of the directory's dentry. This allows sysfs to do
reference counting directly on the kobject when the file is opened and
closed. 


Attributes
~~~~~~~~~~

Attributes can be exported for kobjects in the form of regular files in
the filesystem. Sysfs forwards file I/O operations to methods defined
for the attributes, providing a means to read and write kernel
attributes.

Attributes should be ASCII text files, preferably with only one value
per file. It is noted that it may not be efficient to contain only one
value per file, so it is socially acceptable to express an array of
values of the same type. 

Mixing types, expressing multiple lines of data, and doing fancy
formatting of data is heavily frowned upon. Doing these things may get
you publically humiliated and your code rewritten without notice. 


An attribute definition is simply:

struct attribute {
        char                    * name;
        mode_t                  mode;
};


int sysfs_create_file(struct kobject * kobj, struct attribute * attr);
void sysfs_remove_file(struct kobject * kobj, struct attribute * attr);


A bare attribute contains no means to read or write the value of the
attribute. Subsystems are encouraged to define their own attribute
structure and wrapper functions for adding and removing attributes for
a specific object type. 

For example, the driver model defines struct device_attribute like:

struct device_attribute {
        struct attribute        attr;
        ssize_t (*show)(struct device * dev, char * buf);
        ssize_t (*store)(struct device * dev, const char * buf);
};

int device_create_file(struct device *, struct device_attribute *);
void device_remove_file(struct device *, struct device_attribute *);

It also defines this helper for defining device attributes: 

#define DEVICE_ATTR(_name, _mode, _show, _store)      \
struct device_attribute dev_attr_##_name = {            \
        .attr = {.name  = __stringify(_name) , .mode   = _mode },      \
        .show   = _show,                                \
        .store  = _store,                               \
};

For example, declaring

static DEVICE_ATTR(foo, S_IWUSR | S_IRUGO, show_foo, store_foo);

is equivalent to doing:

static struct device_attribute dev_attr_foo = {
       .attr	= {
		.name = "foo",
		.mode = S_IWUSR | S_IRUGO,
	},
	.show = show_foo,
	.store = store_foo,
};


Subsystem-Specific Callbacks
~~~~~~~~~~~~~~~~~~~~~~~~~~~~

When a subsystem defines a new attribute type, it must implement a
set of sysfs operations for forwarding read and write calls to the
show and store methods of the attribute owners. 

struct sysfs_ops {
        ssize_t (*show)(struct kobject *, struct attribute *, char *);
        ssize_t (*store)(struct kobject *, struct attribute *, const char *);
};

[ Subsystems should have already defined a struct kobj_type as a
descriptor for this type, which is where the sysfs_ops pointer is
stored. See the kobject documentation for more information. ]

When a file is read or written, sysfs calls the appropriate method
for the type. The method then translates the generic struct kobject
and struct attribute pointers to the appropriate pointer types, and
calls the associated methods. 


To illustrate:

#define to_dev_attr(_attr) container_of(_attr, struct device_attribute, attr)
#define to_dev(d) container_of(d, struct device, kobj)

static ssize_t
dev_attr_show(struct kobject * kobj, struct attribute * attr, char * buf)
{
        struct device_attribute * dev_attr = to_dev_attr(attr);
        struct device * dev = to_dev(kobj);
        ssize_t ret = 0;

        if (dev_attr->show)
                ret = dev_attr->show(dev, buf);
        return ret;
}


Reading/Writing Attribute Data
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

To read or write attributes, show() or store() methods must be
specified when declaring the attribute. The method types should be as
simple as those defined for device attributes:

        ssize_t (*show)(struct device * dev, char * buf);
        ssize_t (*store)(struct device * dev, const char * buf);

IOW, they should take only an object and a buffer as parameters. 


sysfs allocates a buffer of size (PAGE_SIZE) and passes it to the
method. Sysfs will call the method exactly once for each read or
write. This forces the following behavior on the method
implementations: 

- On read(2), the show() method should fill the entire buffer. 
  Recall that an attribute should only be exporting one value, or an
  array of similar values, so this shouldn't be that expensive. 

  This allows userspace to do partial reads and forward seeks
  arbitrarily over the entire file at will. If userspace seeks back to
  zero or does a pread(2) with an offset of '0' the show() method will
  be called again, rearmed, to fill the buffer.

- On write(2), sysfs expects the entire buffer to be passed during the
  first write. Sysfs then passes the entire buffer to the store()
  method. 
  
  When writing sysfs files, userspace processes should first read the
  entire file, modify the values it wishes to change, then write the
  entire buffer back. 

  Attribute method implementations should operate on an identical
  buffer when reading and writing values. 

Other notes:

- Writing causes the show() method to be rearmed regardless of current
  file position.

- The buffer will always be PAGE_SIZE bytes in length. On i386, this
  is 4096. 

- show() methods should return the number of bytes printed into the
  buffer. This is the return value of snprintf().

- show() should always use snprintf(). 

- store() should return the number of bytes used from the buffer. This
  can be done using strlen().

- show() or store() can always return errors. If a bad value comes
  through, be sure to return an error.

- The object passed to the methods will be pinned in memory via sysfs
  referencing counting its embedded object. However, the physical 
  entity (e.g. device) the object represents may not be present. Be 
  sure to have a way to check this, if necessary. 


A very simple (and naive) implementation of a device attribute is:

static ssize_t show_name(struct device *dev, struct device_attribute *attr, char *buf)
{
	return snprintf(buf, PAGE_SIZE, "%s\n", dev->name);
}

static ssize_t store_name(struct device * dev, const char * buf)
{
	sscanf(buf, "%20s", dev->name);
	return strnlen(buf, PAGE_SIZE);
}

static DEVICE_ATTR(name, S_IRUGO, show_name, store_name);


(Note that the real implementation doesn't allow userspace to set the 
name for a device.)


Top Level Directory Layout
~~~~~~~~~~~~~~~~~~~~~~~~~~

The sysfs directory arrangement exposes the relationship of kernel
data structures. 

The top level sysfs directory looks like:

block/
bus/
class/
dev/
devices/
firmware/
net/
fs/

devices/ contains a filesystem representation of the device tree. It maps
directly to the internal kernel device tree, which is a hierarchy of
struct device. 

bus/ contains flat directory layout of the various bus types in the
kernel. Each bus's directory contains two subdirectories:

	devices/
	drivers/

devices/ contains symlinks for each device discovered in the system
that point to the device's directory under root/.

drivers/ contains a directory for each device driver that is loaded
for devices on that particular bus (this assumes that drivers do not
span multiple bus types).

fs/ contains a directory for some filesystems.  Currently each
filesystem wanting to export attributes must create its own hierarchy
below fs/ (see ./fuse.txt for an example).

dev/ contains two directories char/ and block/. Inside these two
directories there are symlinks named <major>:<minor>.  These symlinks
point to the sysfs directory for the given device.  /sys/dev provides a
quick way to lookup the sysfs interface for a device from the result of
a stat(2) operation.

More information can driver-model specific features can be found in
Documentation/driver-model/. 


TODO: Finish this section.


Current Interfaces
~~~~~~~~~~~~~~~~~~

The following interface layers currently exist in sysfs:


- devices (include/linux/device.h)
----------------------------------
Structure:

struct device_attribute {
        struct attribute        attr;
        ssize_t (*show)(struct device * dev, char * buf);
        ssize_t (*store)(struct device * dev, const char * buf);
};

Declaring:

DEVICE_ATTR(_name, _str, _mode, _show, _store);

Creation/Removal:

int device_create_file(struct device *device, struct device_attribute * attr);
void device_remove_file(struct device * dev, struct device_attribute * attr);


- bus drivers (include/linux/device.h)
--------------------------------------
Structure:

struct bus_attribute {
        struct attribute        attr;
        ssize_t (*show)(struct bus_type *, char * buf);
        ssize_t (*store)(struct bus_type *, const char * buf);
};

Declaring:

BUS_ATTR(_name, _mode, _show, _store)

Creation/Removal:

int bus_create_file(struct bus_type *, struct bus_attribute *);
void bus_remove_file(struct bus_type *, struct bus_attribute *);


- device drivers (include/linux/device.h)
-----------------------------------------

Structure:

struct driver_attribute {
        struct attribute        attr;
        ssize_t (*show)(struct device_driver *, char * buf);
        ssize_t (*store)(struct device_driver *, const char * buf);
};

Declaring:

DRIVER_ATTR(_name, _mode, _show, _store)

Creation/Removal:

int driver_create_file(struct device_driver *, struct driver_attribute *);
void driver_remove_file(struct device_driver *, struct driver_attribute *);
Commit	Line	Data
	1
	2	sysfs - _The_ filesystem for exporting kernel objects.
	3
	4	Patrick Mochel <mochel@osdl.org>
	5
	6	10 January 2003
	7
	8
	9	What it is:
	10	~~~~~~~~~~~
	11
	12	sysfs is a ram-based filesystem initially based on ramfs. It provides
	13	a means to export kernel data structures, their attributes, and the
	14	linkages between them to userspace.
	15
	16	sysfs is tied inherently to the kobject infrastructure. Please read
	17	Documentation/kobject.txt for more information concerning the kobject
	18	interface.
	19
	20
	21	Using sysfs
	22	~~~~~~~~~~~
	23
	24	sysfs is always compiled in. You can access it by doing:
	25
	26	mount -t sysfs sysfs /sys
	27
	28
	29	Directory Creation
	30	~~~~~~~~~~~~~~~~~~
	31
	32	For every kobject that is registered with the system, a directory is
	33	created for it in sysfs. That directory is created as a subdirectory
	34	of the kobject's parent, expressing internal object hierarchies to
	35	userspace. Top-level directories in sysfs represent the common
	36	ancestors of object hierarchies; i.e. the subsystems the objects
	37	belong to.
	38
	39	Sysfs internally stores the kobject that owns the directory in the
	40	->d_fsdata pointer of the directory's dentry. This allows sysfs to do
	41	reference counting directly on the kobject when the file is opened and
	42	closed.
	43
	44
	45	Attributes
	46	~~~~~~~~~~
	47
	48	Attributes can be exported for kobjects in the form of regular files in
	49	the filesystem. Sysfs forwards file I/O operations to methods defined
	50	for the attributes, providing a means to read and write kernel
	51	attributes.
	52
	53	Attributes should be ASCII text files, preferably with only one value
	54	per file. It is noted that it may not be efficient to contain only one
	55	value per file, so it is socially acceptable to express an array of
	56	values of the same type.
	57
	58	Mixing types, expressing multiple lines of data, and doing fancy
	59	formatting of data is heavily frowned upon. Doing these things may get
	60	you publically humiliated and your code rewritten without notice.
	61
	62
	63	An attribute definition is simply:
	64
	65	struct attribute {
	66	char * name;
	67	mode_t mode;
	68	};
	69
	70
	71	int sysfs_create_file(struct kobject * kobj, struct attribute * attr);
	72	void sysfs_remove_file(struct kobject * kobj, struct attribute * attr);
	73
	74
	75	A bare attribute contains no means to read or write the value of the
	76	attribute. Subsystems are encouraged to define their own attribute
	77	structure and wrapper functions for adding and removing attributes for
	78	a specific object type.
	79
	80	For example, the driver model defines struct device_attribute like:
	81
	82	struct device_attribute {
	83	struct attribute attr;
	84	ssize_t (show)(struct device dev, char * buf);
	85	ssize_t (store)(struct device dev, const char * buf);
	86	};
	87
	88	int device_create_file(struct device , struct device_attribute );
	89	void device_remove_file(struct device , struct device_attribute );
	90
	91	It also defines this helper for defining device attributes:
	92
	93	#define DEVICE_ATTR(_name, _mode, _show, _store) \
	94	struct device_attribute dev_attr_##_name = { \
	95	.attr = {.name = __stringify(_name) , .mode = _mode }, \
	96	.show = _show, \
	97	.store = _store, \
	98	};
	99
	100	For example, declaring
	101
	102	static DEVICE_ATTR(foo, S_IWUSR \| S_IRUGO, show_foo, store_foo);
	103
	104	is equivalent to doing:
	105
	106	static struct device_attribute dev_attr_foo = {
	107	.attr = {
	108	.name = "foo",
	109	.mode = S_IWUSR \| S_IRUGO,
	110	},
	111	.show = show_foo,
	112	.store = store_foo,
	113	};
	114
	115
	116	Subsystem-Specific Callbacks
	117	~~~~~~~~~~~~~~~~~~~~~~~~~~~~
	118
	119	When a subsystem defines a new attribute type, it must implement a
	120	set of sysfs operations for forwarding read and write calls to the
	121	show and store methods of the attribute owners.
	122
	123	struct sysfs_ops {
	124	ssize_t (show)(struct kobject , struct attribute , char );
	125	ssize_t (store)(struct kobject , struct attribute , const char );
	126	};
	127
	128	[ Subsystems should have already defined a struct kobj_type as a
	129	descriptor for this type, which is where the sysfs_ops pointer is
	130	stored. See the kobject documentation for more information. ]
	131
	132	When a file is read or written, sysfs calls the appropriate method
	133	for the type. The method then translates the generic struct kobject
	134	and struct attribute pointers to the appropriate pointer types, and
	135	calls the associated methods.
	136
	137
	138	To illustrate:
	139
	140	#define to_dev_attr(_attr) container_of(_attr, struct device_attribute, attr)
	141	#define to_dev(d) container_of(d, struct device, kobj)
	142
	143	static ssize_t
	144	dev_attr_show(struct kobject * kobj, struct attribute * attr, char * buf)
	145	{
	146	struct device_attribute * dev_attr = to_dev_attr(attr);
	147	struct device * dev = to_dev(kobj);
	148	ssize_t ret = 0;
	149
	150	if (dev_attr->show)
	151	ret = dev_attr->show(dev, buf);
	152	return ret;
	153	}
	154
	155
	156
	157	Reading/Writing Attribute Data
	158	~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
	159
	160	To read or write attributes, show() or store() methods must be
	161	specified when declaring the attribute. The method types should be as
	162	simple as those defined for device attributes:
	163
	164	ssize_t (show)(struct device dev, char * buf);
	165	ssize_t (store)(struct device dev, const char * buf);
	166
	167	IOW, they should take only an object and a buffer as parameters.
	168
	169
	170	sysfs allocates a buffer of size (PAGE_SIZE) and passes it to the
	171	method. Sysfs will call the method exactly once for each read or
	172	write. This forces the following behavior on the method
	173	implementations:
	174
	175	- On read(2), the show() method should fill the entire buffer.
	176	Recall that an attribute should only be exporting one value, or an
	177	array of similar values, so this shouldn't be that expensive.
	178
	179	This allows userspace to do partial reads and forward seeks
	180	arbitrarily over the entire file at will. If userspace seeks back to
	181	zero or does a pread(2) with an offset of '0' the show() method will
	182	be called again, rearmed, to fill the buffer.
	183
	184	- On write(2), sysfs expects the entire buffer to be passed during the
	185	first write. Sysfs then passes the entire buffer to the store()
	186	method.
	187
	188	When writing sysfs files, userspace processes should first read the
	189	entire file, modify the values it wishes to change, then write the
	190	entire buffer back.
	191
	192	Attribute method implementations should operate on an identical
	193	buffer when reading and writing values.
	194
	195	Other notes:
	196
	197	- Writing causes the show() method to be rearmed regardless of current
	198	file position.
	199
	200	- The buffer will always be PAGE_SIZE bytes in length. On i386, this
	201	is 4096.
	202
	203	- show() methods should return the number of bytes printed into the
	204	buffer. This is the return value of snprintf().
	205
	206	- show() should always use snprintf().
	207
	208	- store() should return the number of bytes used from the buffer. This
	209	can be done using strlen().
	210
	211	- show() or store() can always return errors. If a bad value comes
	212	through, be sure to return an error.
	213
	214	- The object passed to the methods will be pinned in memory via sysfs
	215	referencing counting its embedded object. However, the physical
	216	entity (e.g. device) the object represents may not be present. Be
	217	sure to have a way to check this, if necessary.
	218
	219
	220	A very simple (and naive) implementation of a device attribute is:
	221
	222	static ssize_t show_name(struct device dev, struct device_attribute attr, char *buf)
	223	{
	224	return snprintf(buf, PAGE_SIZE, "%s\n", dev->name);
	225	}
	226
	227	static ssize_t store_name(struct device * dev, const char * buf)
	228	{
	229	sscanf(buf, "%20s", dev->name);
	230	return strnlen(buf, PAGE_SIZE);
	231	}
	232
	233	static DEVICE_ATTR(name, S_IRUGO, show_name, store_name);
	234
	235
	236	(Note that the real implementation doesn't allow userspace to set the
	237	name for a device.)
	238
	239
	240	Top Level Directory Layout
	241	~~~~~~~~~~~~~~~~~~~~~~~~~~
	242
	243	The sysfs directory arrangement exposes the relationship of kernel
	244	data structures.
	245
	246	The top level sysfs directory looks like:
	247
	248	block/
	249	bus/
	250	class/
	251	dev/
	252	devices/
	253	firmware/
	254	net/
	255	fs/
	256
	257	devices/ contains a filesystem representation of the device tree. It maps
	258	directly to the internal kernel device tree, which is a hierarchy of
	259	struct device.
	260
	261	bus/ contains flat directory layout of the various bus types in the
	262	kernel. Each bus's directory contains two subdirectories:
	263
	264	devices/
	265	drivers/
	266
	267	devices/ contains symlinks for each device discovered in the system
	268	that point to the device's directory under root/.
	269
	270	drivers/ contains a directory for each device driver that is loaded
	271	for devices on that particular bus (this assumes that drivers do not
	272	span multiple bus types).
	273
	274	fs/ contains a directory for some filesystems. Currently each
	275	filesystem wanting to export attributes must create its own hierarchy
	276	below fs/ (see ./fuse.txt for an example).
	277
	278	dev/ contains two directories char/ and block/. Inside these two
	279	directories there are symlinks named <major>:<minor>. These symlinks
	280	point to the sysfs directory for the given device. /sys/dev provides a
	281	quick way to lookup the sysfs interface for a device from the result of
	282	a stat(2) operation.
	283
	284	More information can driver-model specific features can be found in
	285	Documentation/driver-model/.
	286
	287
	288	TODO: Finish this section.
	289
	290
	291	Current Interfaces
	292	~~~~~~~~~~~~~~~~~~
	293
	294	The following interface layers currently exist in sysfs:
	295
	296
	297	- devices (include/linux/device.h)
	298	----------------------------------
	299	Structure:
	300
	301	struct device_attribute {
	302	struct attribute attr;
	303	ssize_t (show)(struct device dev, char * buf);
	304	ssize_t (store)(struct device dev, const char * buf);
	305	};
	306
	307	Declaring:
	308
	309	DEVICE_ATTR(_name, _str, _mode, _show, _store);
	310
	311	Creation/Removal:
	312
	313	int device_create_file(struct device device, struct device_attribute attr);
	314	void device_remove_file(struct device * dev, struct device_attribute * attr);
	315
	316
	317	- bus drivers (include/linux/device.h)
	318	--------------------------------------
	319	Structure:
	320
	321	struct bus_attribute {
	322	struct attribute attr;
	323	ssize_t (show)(struct bus_type , char * buf);
	324	ssize_t (store)(struct bus_type , const char * buf);
	325	};
	326
	327	Declaring:
	328
	329	BUS_ATTR(_name, _mode, _show, _store)
	330
	331	Creation/Removal:
	332
	333	int bus_create_file(struct bus_type , struct bus_attribute );
	334	void bus_remove_file(struct bus_type , struct bus_attribute );
	335
	336
	337	- device drivers (include/linux/device.h)
	338	-----------------------------------------
	339
	340	Structure:
	341
	342	struct driver_attribute {
	343	struct attribute attr;
	344	ssize_t (show)(struct device_driver , char * buf);
	345	ssize_t (store)(struct device_driver , const char * buf);
	346	};
	347
	348	Declaring:
	349
	350	DRIVER_ATTR(_name, _mode, _show, _store)
	351
	352	Creation/Removal:
	353
	354	int driver_create_file(struct device_driver , struct driver_attribute );
	355	void driver_remove_file(struct device_driver , struct driver_attribute );
	356
	357